CN111446366A - Method for modifying graphene, carbon nano tube or composite transparent conductive film thereof by gel type polymer electrolyte and application - Google Patents

Method for modifying graphene, carbon nano tube or composite transparent conductive film thereof by gel type polymer electrolyte and application Download PDF

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CN111446366A
CN111446366A CN201910045199.2A CN201910045199A CN111446366A CN 111446366 A CN111446366 A CN 111446366A CN 201910045199 A CN201910045199 A CN 201910045199A CN 111446366 A CN111446366 A CN 111446366A
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杜金红
佟博
任文才
张鼎冬
张伟民
成会明
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Institute of Metal Research of CAS
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Abstract

The invention relates to the field of modification and application of high-performance graphene, carbon nanotubes or composite transparent conductive films thereof, in particular to a method for modifying graphene, carbon nanotubes or composite transparent conductive films thereof by using a gel polymer electrolyte and application thereof. Firstly, preparing inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte solution by a copolymerization-dilution method; and then coating the surface of the graphene, the carbon nano tube or the composite transparent conductive film thereof with a spin coating method and the like, and drying to form a film, thereby realizing the modification of the graphene, the carbon nano tube or the composite transparent conductive film thereof by the gel polymer electrolyte. The method has simple process and easy operation, the conductivity and the surface wettability of the graphene and the carbon nano tube or the composite transparent conductive film thereof modified by the gel polymer electrolyte are obviously improved, and the work function is adjustable, so the method has practical application value in the field of photoelectric devices such as organic light-emitting diodes, organic solar cells, perovskite solar cells and the like.

Description

Method for modifying graphene, carbon nano tube or composite transparent conductive film thereof by gel type polymer electrolyte and application
Technical Field
The invention relates to the field of modification and application of high-performance graphene, carbon nanotubes or composite transparent conductive films thereof, in particular to a method and application of modifying graphene, carbon nanotubes or composite transparent conductive films thereof with gel polymer electrolyte, improving the conductivity and surface wettability of the graphene, carbon nanotubes or composite transparent conductive films thereof, and regulating and controlling the work function of the graphene, carbon nanotubes or composite transparent conductive films.
Background
The graphene, the carbon nanotube and the composite transparent conductive film thereof are expected to be widely used as transparent electrode materials of photoelectric devices such as flexible organic light-emitting diodes and organic solar cells due to high transparency, high conductivity and excellent flexibility. However, the conductivity and surface wettability of graphene, carbon nanotubes and their composite transparent conductive films still need to be improved, so as to facilitate the processing of devices and improve the performance of devices. More importantly, in order to widen the application of the graphene, the carbon nanotube and the composite transparent conductive film thereof, the graphene, the carbon nanotube and the composite transparent conductive film thereof can be used as an anode of a photoelectric device, a cathode and a middle electrode of a laminated device, and the work functions of the graphene, the carbon nanotube and the composite transparent conductive film need to be regulated and controlled.
The inorganic metal salt deposited on the surface of graphene, carbon nanotube and composite film thereof can effectively improve the conductivity and regulate the work function thereof, for example, inorganic alkali metal salt, L iCl, Cs2CO3The conductivity of the graphene, the carbon nano tube and the composite film thereof can be improved by n-type doping, and the work function of the graphene, the carbon nano tube and the composite film thereof can be reduced; and AuCl3、CuCl2And the inorganic metal salt can improve the conductivity and work function of the graphene, the carbon nano tube and the composite film thereof by p-type doping. However, the doping effect is extremely unstable, and the inorganic metal salt is gradually agglomerated or oxidized, so that the conductivity of the doped film is gradually reduced. Furthermore, grapheneThe non-wetting property of the surface of the carbon nano tube and the composite transparent conductive film thereof is not beneficial to the deposition of inorganic metal salt solution on the surface, and the practical application of the inorganic metal salt solution in devices is limited.
The gel type polymer electrolyte is formed by complexing inorganic metal salt and gel polymer. The doping of different inorganic metal salts can realize the regulation and control of the work functions of the graphene, the carbon nano tube and the composite transparent conductive film and improve the conductivity of the graphene, the carbon nano tube and the composite transparent conductive film. The gel-type polymer matrix can fix and protect the metal salt to avoid agglomeration and oxidation, thereby improving the stability of the metal salt. In addition, the gel polymer matrix has good interface compatibility with graphene, carbon nanotubes and the composite transparent conductive film thereof, so that the gel polymer matrix is easy to form a film on the surfaces of the graphene, the carbon nanotubes and the composite film thereof, can improve the compatibility of the graphene, the carbon nanotubes and the composite transparent conductive film thereof with other functional layers, is beneficial to processing devices, and has important significance in promoting the wide application of the graphene, the carbon nanotubes and the composite transparent conductive film thereof in photoelectric devices.
Disclosure of Invention
The invention aims to provide a method for modifying graphene, carbon nanotubes or a composite transparent conductive film thereof by using a gel-type polymer electrolyte and application thereof. The graphene and the carbon nano tube or the composite transparent conductive film thereof modified by the gel polymer electrolyte have good surface wettability, light transmittance and conductivity and adjustable work function, and can be widely applied to transparent cathodes and anodes of photoelectric devices such as organic light-emitting diodes, organic solar cells or perovskite solar cells and the like and intermediate electrodes of laminated devices.
The technical scheme of the invention is as follows:
a method for modifying graphene, carbon nano tubes or a composite transparent conductive film thereof by using a gel type polymer electrolyte is characterized in that an inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte solution is prepared by a copolymerization-dilution method and is coated on the surface of the graphene, the carbon nano tubes or the composite transparent conductive film thereof to form a film in a drying manner, so that the surface characteristic of the transparent conductive film is improved.
The method for modifying graphene, carbon nano tube or composite transparent conductive film thereof by using gel type polymer electrolyte, wherein the specific process for preparing inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte solution by using a copolymerization-dilution method comprises the following steps: dissolving anhydrous citric acid in an organic solvent, and ultrasonically mixing the dissolved anhydrous citric acid with tetraethoxysilane to form a citric acid-tetraethoxysilane gel type polymer matrix; then adding different inorganic metal salts and ethylene glycol, heating and stirring to obtain the gel polymer electrolyte, and finally diluting the gel polymer electrolyte to adjust the concentration.
According to the method for modifying graphene, carbon nano tubes or composite transparent conductive films thereof by using the gel-type polymer electrolyte, an organic solvent used for dissolving citric acid is one of absolute ethyl alcohol, methanol, isopropanol or acetonitrile, the concentration of a citric acid solution is 0.4 mol/L-6 mol/L, and the molar ratio of the mixed ethyl orthosilicate to the citric acid is 1: 2-2: 1.
According to the method for modifying graphene, carbon nano tubes or composite transparent conductive films thereof by using the gel type polymer electrolyte, metal salts used in the inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte are lithium chloride, lithium perchlorate, lithium hexafluorophosphate, lithium carbonate, cesium carbonate, magnesium carbonate, copper chloride or gold chloride; the molar ratio of metal ions in the metal salt to the citric acid-ethyl orthosilicate gel type polymer matrix is 1: 4-5: 1, and the molar ratio of metal ions in the metal salt to ethylene glycol is 1: 4-5: 2; the heating and stirring temperature is 30-80 ℃, and the time is 1-4 h.
According to the method for modifying graphene, carbon nano tubes or composite transparent conductive films thereof by using the gel type polymer electrolyte, a solvent used for diluting the inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte is one of absolute ethyl alcohol, methanol, isopropanol or acetonitrile, and the concentration of the obtained inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte solution is 2-20 wt%.
According to the method for modifying the graphene, the carbon nano tube or the composite transparent conductive film thereof by using the gel polymer electrolyte, the thickness of the conductive layer of the graphene, the carbon nano tube or the composite transparent conductive film thereof is 1-50 nm.
The method for modifying the graphene and the carbon nano tube or the composite transparent conductive film thereof by the gel polymer electrolyte comprises the steps of spin coating, spray coating, blade coating, roller coating or dip-coating, wherein the drying and film forming temperature is 40-120 ℃, the time is 30-120 min, and the film thickness is 5-30 nm.
According to the method for modifying graphene, carbon nanotubes or composite transparent conductive film thereof by using the gel polymer electrolyte, the performance indexes of the graphene, the carbon nanotubes or the composite transparent conductive film modified by using the gel polymer electrolyte are as follows: the surface resistance is 30-400 omega/□, the light transmittance at 550nm is 75-97%, the work function is 3.0-5.5 eV, and the surface wetting angle is 15-35 degrees.
The graphene and the carbon nanotube modified by the gel polymer electrolyte or the composite transparent conductive film thereof have high conductivity and surface wettability, and the work function is adjustable, so that the gel polymer electrolyte modified graphene and the carbon nanotube or the composite transparent conductive film thereof can be widely applied to transparent cathodes, anodes or intermediate electrodes of laminated devices of photoelectric devices such as organic light-emitting diodes, organic solar cells or perovskite solar cells.
The design idea of the invention is as follows:
the gel-type polymer electrolyte is prepared by complexing inorganic metal salt and gel polymer, firstly preparing gel-type polymer electrolyte solution by complexing metal salt with different work functions and gel polymer, and then coating the gel-type polymer electrolyte solution on the surface of graphene, carbon nano tube or composite transparent conductive film thereof to modify the graphene, carbon nano tube or composite transparent conductive film thereof, wherein inorganic alkali metal salt (such as L iCl, Cs) is selected2CO3、MgCO3) The conductivity of the graphene, the carbon nano tube or the composite transparent conductive film thereof can be improved through n-type doping, and the work function of the graphene, the carbon nano tube or the composite transparent conductive film thereof can be reduced; and AuCl is selected3、CuCl2And the inorganic metal salt can improve the conductivity of the graphene, the carbon nano tube or the composite transparent conductive film thereof through p-type doping and improve the work function of the graphene and the carbon nano tube, so that the regulation and control of the work function of the graphene can be realized. At the same time, using gelsThe metal salt agglomeration and oxidation can be reduced by the fixing and protecting action of the polymer matrix, so that the stability of the doped graphene, the carbon nano tube or the composite transparent conductive film thereof can be improved. In addition, by utilizing the characteristic that the gel polymer matrix has good interface compatibility with graphene, carbon nanotubes or a composite transparent conductive film thereof, the gel polymer electrolyte can uniformly form a film on the surface of the graphene. Meanwhile, the compatibility of graphene, carbon nanotubes or composite transparent conductive films thereof with other functional layers can be improved, the processing of devices is facilitated, and the performance of the devices is improved.
The invention has the advantages and beneficial effects that:
1. the invention develops a 'copolymerization method' for synthesizing inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte, the gel type polymer electrolyte is an organic-inorganic hybrid polymer, ion conductivity and electronic conductivity can be considered, and the preparation method is simple in preparation process, rich in raw materials and low in cost.
2. The invention provides a gel polymer electrolyte modified graphene, a carbon nano tube or a composite transparent conductive film thereof for modifying, so that the conductivity and the surface wettability of the graphene and the carbon nano tube can be improved, and the work function of the graphene and the carbon nano tube can be regulated and controlled.
3. The gel-type polymer electrolyte modified graphene, the carbon nano tube or the composite transparent conductive film thereof obtained by the invention has important practical value, and can be widely applied to transparent cathodes and anodes of photoelectric devices such as organic light-emitting diodes, organic solar cells, perovskite solar cells and the like and intermediate electrodes of laminated devices.
Drawings
Fig. 1 is a schematic flow chart of a method for modifying graphene, carbon nanotubes or a composite transparent conductive film thereof by using a gel-type polymer electrolyte according to the present invention.
Fig. 2 is an optical photograph of the gel-type polymer electrolyte modified graphene transparent conductive film in example 1.
Detailed Description
In the specific implementation process, as shown in fig. 1, the invention firstly prepares the inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte solution by a "copolymerization-dilution" method, and the specific process is as follows:
firstly, dissolving anhydrous citric acid in an organic solvent such as anhydrous ethanol, isopropanol, methanol or acetonitrile, wherein the concentration of the anhydrous citric acid is 0.4 mol/L-6 mol/L, then ultrasonically mixing the anhydrous citric acid with ethyl orthosilicate (the molar ratio is 1: 2-2: 1) to form a citric acid-ethyl orthosilicate gel type polymer matrix, then adding lithium chloride, lithium perchlorate, lithium hexafluorophosphate, lithium carbonate, copper chloride or gold chloride and other different inorganic metal salts and ethylene glycol (the molar ratio of the metal ions to the citric acid-ethyl orthosilicate gel type polymer matrix is 1: 4-5: 1, and the molar ratio of the metal ions to the ethylene glycol is 1: 4-5: 2), heating and stirring the mixture at the temperature of 30-80 ℃ for 1-4 h to obtain a gel type polymer electrolyte, and then diluting the gel type polymer electrolyte by using anhydrous ethanol, isopropanol, methanol or acetonitrile and the like to adjust the concentration of the anhydrous citric acid to 2-20 wt% to form the gel type polymer electrolyte solution.
Then, coating (depositing) an inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte solution on the surface of the graphene, the carbon nano tube or the composite transparent conductive film of the graphene and the carbon nano tube with the conductive layer thickness of 1-50 nm by methods of spin coating, spray coating and the like; drying at 40-120 ℃ for 30-120 min to form a film with a thickness of 5-30 nm.
And finally, applying the graphene and the carbon nano tube modified by the inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte or the composite transparent conductive film thereof to transparent electrodes of photoelectric devices such as organic light-emitting diodes, organic solar cells and perovskite solar cells and intermediate electrodes of laminated devices.
The present invention will be described in further detail below with reference to examples.
Example 1
In this example, first, a lithium perchlorate/citric acid-tetraethoxysilane gel type polymer electrolyte solution is prepared by a "copolymerization-dilution" method, and the specific process is as follows: dissolving 0.2mol of anhydrous citric acid in 50ml of anhydrous ethanol, and ultrasonically mixing the anhydrous citric acid with 0.1mol of tetraethoxysilane to form a citric acid-tetraethoxysilane gel type polymer matrix; then 0.1mol of anhydrous lithium perchlorate and 5g of glycol are added at 60 DEG CHeating and stirring for 2h to obtain gel type polymer electrolyte L i+And citric acid-tetraethylorthosilicate gel-type polymer matrix at a molar ratio of 1: 1. Subsequently, the prepared gel-type polymer electrolyte was diluted to a mass fraction of 5 wt% using anhydrous ethanol.
Then, the prepared lithium perchlorate/citric acid-ethyl orthosilicate gel type polymer electrolyte solution is coated on the surface of a graphene transparent conductive film with the thickness of 1nm by adopting a spin coating method, and the graphene transparent conductive film is dried at 60 ℃ for 60min to form a film with the thickness of 22 nm. As shown in fig. 2, an optical photograph of the obtained gel-type electrolyte-modified graphene transparent conductive film showed a surface resistance of 352 Ω/□, a light transmittance at 550nm of 95.7%, a work function of 3.28eV, and a surface wetting angle of 22.5 °.
The transparent conductive film is used as a cathode to prepare the graphene/TiO modified by the gel polymer electrolyte2The perovskite solar cell of/CH 3NH3PbI3/P3HT/Au has the conversion efficiency of 10 percent.
Example 2
The difference from example 1 is that lithium hexafluorophosphate is used as the inorganic metal salt in the preparation of the gel type polymer electrolyte, and after ethylene glycol is added, the gel type polymer electrolyte is prepared by heating and stirring at 30 ℃ for 4 hours and then diluted to a mass fraction of 20 wt%.
And forming a film on the surface of the graphene transparent conductive film with the conductive layer thickness of 3nm by using lithium hexafluorophosphate/citric acid-ethyl orthosilicate, wherein the thickness of the film is 20 nm. The surface resistance of the graphene transparent conductive film modified by the gel electrolyte is 162 omega/□, the light transmittance at 550nm is 91.9%, the work function is 3.36eV, and the surface wetting angle is 20.2 degrees.
The transparent conductive film is used as a cathode to prepare the graphene/L iF/Bphen/Bepp modified by gel polymer electrolyte2/Bepp2:10%Ir(ppy)2(acac)/TAPC/MoO3An Al organic light emitting diode with a power efficiency of 55lm W-1
Example 3
The difference from example 1 is that the inorganic metal salt used in the preparation of the gel-type polymer electrolyte is lithium carbonate. After adding ethylene glycol, heating and stirring the mixture for 1 hour at the temperature of 80 ℃ to prepare the gel type polymer electrolyte, and then diluting the gel type polymer electrolyte until the mass fraction is 15 wt%.
And forming a film on the surface of the graphene transparent conductive film with the thickness of 5nm of the conductive layer by lithium carbonate/citric acid-ethyl orthosilicate, wherein the thickness of the film is 25 nm. The surface resistance of the graphene transparent conductive film modified by the gel electrolyte is 155 omega/□, the light transmittance at 550nm is 85.2%, the work function is 3.25eV, and the surface wetting angle is 24.7 degrees.
The transparent conductive film is used as an intermediate electrode to prepare ITO/PEDOT, PSS/P3HT, PCBM/gel polymer electrolyte modified graphene/MoO3The conversion efficiency of the/ZnPc C60/L iF/Al organic solar cell is 2.9 percent.
Example 4:
the difference from example 1 is that the solvent used in the preparation of the gel-type polymer electrolyte is isopropanol, the inorganic metal salt is lithium chloride, and the diluted solution is diluted with isopropanol, and the mass fraction of the diluted solution is 10 wt%.
And coating a lithium chloride/citric acid-ethyl orthosilicate gel type polymer electrolyte solution on the surface of the graphene transparent conductive film with the thickness of 1nm and the thickness of 16 nm. The surface resistance of the gel-type electrolyte modified graphene transparent conductive film is 385 omega/□, the light transmittance at 550nm is 96.2%, the work function is 3.47eV, and the surface wetting angle is 32.6 degrees.
The transparent conductive film is used as a cathode to prepare the graphene/L iF/Bphen/Bepp modified by gel polymer electrolyte2/Bepp2:10%Ir(ppy)2(acac)/TAPC/MoO3Al-based organic light-emitting diode with a power efficiency of 63.2 lm.W-1
Example 5
The difference from example 1 is that the solvent used in the preparation of the gel-type polymer electrolyte is methanol, the inorganic metal salt is anhydrous cupric chloride, Cu2+And citric acid-ethyl orthosilicate gel type polymer matrix in a molar ratio of 1:1, diluting with methanol, and the mass fraction of the diluted gel type polymer electrolyte solution is 10 wt%.
The copper chloride/citric acid-ethyl orthosilicate forms a film on the surface of the carbon nano tube transparent conductive film with the thickness of 20nm, and the thickness of the film is 14 nm. The surface resistance of the gel-type electrolyte-modified carbon nanotube transparent conductive film is 265 omega/□, the light transmittance at 550nm is 88.4%, the work function is 4.82eV, and the surface wetting angle is 22.8 degrees.
The transparent conductive film is used as an anode, and the prepared structure is a gel type electrolyte modified carbon nano tube/MoO3/TAPC/Bepp2:10%Ir(ppy)2(acac)/Bepp2The power efficiency of the organic light-emitting diode of/Bphen/L iF/Al is 68.2lm W-1
Example 6
The difference from the example 1 is that the solvent used in the preparation of the gel-type polymer electrolyte is acetonitrile, and the inorganic metal salt is anhydrous gold chloride, Au3+And citric acid-ethyl orthosilicate gel type polymer matrix in a molar ratio of 1:1, diluting with acetonitrile, and the mass fraction of the diluted gel type polymer electrolyte solution is 15 wt%.
Forming a film on the surface of the graphene/carbon nano tube composite transparent conductive film with the thickness of 20nm by using gold chloride/citric acid-ethyl orthosilicate, wherein the thickness of the film is 16 nm; the graphene/carbon nanotube composite transparent conductive film is prepared by transferring graphene to the surface of a carbon nanotube film obtained by a spraying method. The surface resistance of the gel-type electrolyte modified graphene/carbon nanotube composite transparent conductive film is 232 omega/□, the light transmittance at 550nm is 89.3%, the work function is 5.12eV, and the surface wetting angle is 23.5 degrees.
The transparent conductive film is used as an anode to prepare a gel polymer electrolyte modified graphene/carbon nanotube composite film/MoO3/TAPC/Bepp2:10%Ir(ppy)2(acac)/Bepp2The power efficiency of the organic light-emitting diode of/Bphen/L iF/Al is 87.8lm W-1
Example 7
The difference from the embodiment 1 is that lithium perchlorate/citric acid-ethyl orthosilicate gel type polymer electrolyte is deposited on the surface of the graphene transparent conductive film with the conductive layer thickness of 1nm by adopting a spraying method, and the film is formed after drying at 100 ℃ for 40min, wherein the thickness is 31 nm. The surface resistance of the graphene transparent conductive film modified by the lithium perchlorate/citric acid-ethyl orthosilicate gel electrolyte is 355 omega/□, the light transmittance at 550nm is 94.4%, the work function is 3.15eV, and the surface wetting angle is 18.3 degrees.
The transparent conductive film is used as a cathode to prepare the graphene/L iF/Bphen/Bepp modified by gel polymer electrolyte2/Bepp2:10%Ir(ppy)2(acac)/TAPC/MoO3An Al organic light-emitting diode with a power efficiency of 51.2lm W-1
Example 8
The difference from the embodiment 1 is that lithium perchlorate/citric acid-ethyl orthosilicate gel type polymer electrolyte is deposited on the surface of a carbon nano tube transparent conductive film with the conductive layer thickness of 50nm by adopting a dip-coating method, and the film is formed after drying at 120 ℃ for 30min, wherein the thickness is 8 nm. The surface resistivity of the carbon nano tube transparent conductive film modified by the lithium perchlorate/citric acid-ethyl orthosilicate gel polymer electrolyte is 120 omega/□, the light transmittance at 550nm is 78.8%, the work function is 3.12eV, and the surface wetting angle is 35.2 degrees.
The transparent conductive film is used as a cathode to prepare the carbon nano tube/L iF/Bphen/Bepp modified by the gel polymer electrolyte2/Bepp2:10%Ir(ppy)2(acac)/TAPC/MoO3The power efficiency of the Al organic light-emitting diode is 68.2 lm.W-1
The embodiment result shows that the inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte solution is prepared by a copolymerization-dilution method, then is coated on the surface of graphene, carbon nano tubes or composite transparent conductive films thereof by methods such as spin coating and the like, and is dried to form a film at a certain temperature, so that the modification of the graphene, the carbon nano tubes or the composite transparent conductive films thereof by the gel type polymer electrolyte can be realized. The method has simple process and easy operation, the conductivity and the surface wettability of the graphene and the carbon nano tube or the composite transparent conductive film thereof modified by the gel polymer electrolyte are obviously improved, and the work function is adjustable, so the method has practical application value in the field of photoelectric devices such as organic light-emitting diodes, organic solar cells, perovskite solar cells and the like.

Claims (9)

1. A method for modifying graphene, carbon nano tubes or composite transparent conductive films thereof by gel type polymer electrolytes is characterized in that an inorganic metal salt/citric acid-ethyl orthosilicate gel type polymer electrolyte solution is prepared by a copolymerization-dilution method and coated on the surfaces of the graphene, the carbon nano tubes or the composite transparent conductive films thereof to be dried and formed into films so as to improve the surface characteristics of the transparent conductive films.
2. The method for modifying graphene, carbon nanotubes or composite transparent conductive films thereof by using the gel-type polymer electrolyte according to claim 1, wherein the specific process for preparing the inorganic metal salt/citric acid-ethyl orthosilicate gel-type polymer electrolyte solution by using the copolymerization-dilution method comprises the following steps: dissolving anhydrous citric acid in an organic solvent, and ultrasonically mixing the dissolved anhydrous citric acid with tetraethoxysilane to form a citric acid-tetraethoxysilane gel type polymer matrix; then adding different inorganic metal salts and ethylene glycol, heating and stirring to obtain the gel polymer electrolyte, and finally diluting the gel polymer electrolyte to adjust the concentration.
3. The method for modifying the graphene, the carbon nano tube or the composite transparent conductive film thereof by the gel polymer electrolyte according to claim 2, wherein an organic solvent used for dissolving citric acid is one of absolute ethyl alcohol, methanol, isopropanol or acetonitrile, the concentration of the citric acid solution is 0.4 mol/L-6 mol/L, and the molar ratio of the mixed tetraethoxysilane to the citric acid is 1: 2-2: 1.
4. The method for modifying graphene, carbon nanotubes or composite transparent conductive films thereof by using the gel-type polymer electrolyte according to claim 2, wherein the metal salt used in the inorganic metal salt/citric acid-ethyl orthosilicate gel-type polymer electrolyte is lithium chloride, lithium perchlorate, lithium hexafluorophosphate, lithium carbonate, cesium carbonate, magnesium carbonate, copper chloride or gold chloride; the molar ratio of metal ions in the metal salt to the citric acid-ethyl orthosilicate gel type polymer matrix is 1: 4-5: 1, and the molar ratio of metal ions in the metal salt to ethylene glycol is 1: 4-5: 2; the heating and stirring temperature is 30-80 ℃, and the time is 1-4 h.
5. The method for modifying graphene, carbon nanotubes or composite transparent conductive films thereof by using the gel polymer electrolyte as claimed in claim 2, wherein the solvent used for diluting the inorganic metal salt/citric acid-ethyl orthosilicate gel polymer electrolyte is one of absolute ethyl alcohol, methanol, isopropanol or acetonitrile, and the concentration of the obtained inorganic metal salt/citric acid-ethyl orthosilicate gel polymer electrolyte solution is 2-20 wt%.
6. The method for modifying graphene, carbon nanotubes or composite transparent conductive film thereof by using the gel polymer electrolyte as claimed in claim 1, wherein the thickness of the conductive layer of the graphene, carbon nanotubes or composite transparent conductive film thereof is 1-50 nm.
7. The method for modifying graphene, carbon nanotubes or a composite transparent conductive film thereof by using the gel polymer electrolyte as claimed in claim 1, wherein the method for coating the gel polymer electrolyte on the graphene, carbon nanotubes or the composite transparent conductive film thereof is spin coating, spray coating, blade coating, roller coating or dip-coating, the drying and film forming temperature is 40-120 ℃, the time is 30-120 min, and the film thickness is 5-30 nm.
8. The method for modifying graphene, carbon nanotubes or composite transparent conductive film thereof by using gel polymer electrolyte as claimed in claim 1, wherein the performance indexes of the graphene, carbon nanotubes or composite transparent conductive film thereof modified by using gel polymer electrolyte are as follows: the surface resistance is 30-400 omega/□, the light transmittance at 550nm is 75-97%, the work function is 3.0-5.5 eV, and the surface wetting angle is 15-35 degrees.
9. The application of the graphene, the carbon nanotube or the composite transparent conductive film modified by the gel polymer electrolyte according to any one of claims 1 to 8, wherein the graphene, the carbon nanotube or the composite transparent conductive film modified by the gel polymer electrolyte has high conductivity and surface wettability, and the work function is adjustable, so that the graphene, the carbon nanotube or the composite transparent conductive film is widely applied to transparent cathodes, anodes or intermediate electrodes of photoelectric devices such as organic light emitting diodes, organic solar cells or perovskite solar cells.
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